Power-efficient multi-frequency resonant clock meshes

ABSTRACT

Power-efficient resonant clock meshes and multiple frequency resonant clock distribution networks.

RELATIONSHIP TO OTHER APPLICATIONS

This application claims the benefit of and priority to U.S. provisional application No. 61/738,426 filed 18 Dec. 2012, which is hereby incorporated by reference in its entirety.

GOVERNMENT SUPPORT

This invention was made with government support under National Science Foundation grant CCF-1053838. The government has certain rights in the invention.

FIELD OF THE INVENTION

The presently disclosed subject matter is directed towards power-efficient resonant clock meshes. More particularly, the present invention is directed toward multiple frequency resonant clock distribution networks.

BACKGROUND OF THE INVENTION

The on-going demand for high performance electronic systems has driven the need for high-speed digital Very Large Scale Integration (VLSI) chips. VLSI implementations have proceeded in two inter-related directions: higher performance and higher density (more devices per unit area). While modern VLSI chips have achieved astonishingly high levels of performance and chip density, there is a very strong demand for even higher levels.

One serious impediment to achieving what is demanded from VLSI devices is power consumption. As a rule of thumb higher performance requires more power. But, more power produces more heat, which increases failure rates. Consequently, power consumption is the predominant challenge in improving modern high performance systems.

Almost all modern VLSI chips are clocked. That is, the operations of the gates within a VLSI chip are synchronized to act together by clock signals. As long as the gates can keep up, the higher the clock rate the faster the performance. Unfortunately, as clock rates and VLSI chip densities increase it becomes very difficult to ensure that all of the chips can keep up with the clocks. One reason for this is that each sequential element in a VLSI chip needs its own clock signal, but not all devices are the same distance from the clock signal source, which means that all clock lines are not the same length and that associated parameters such as distributed capacitances and resistances, differ. Different lengths coupled with unavoidable signal delays caused by distributed resistances and capacitances mean that clock signals arrive at different devices at different times (clock skew). Such can effectively limit the performance of a VLSI chip.

Compounding the clocking problems is the fact that clocking requires power. In fact, the on-chip clock distribution network (CDN) of modern VLSI chips often consumes more than 35% of the total chip power and can occasionally require as much as 70%.

Various approaches have been attempted in the prior art to address VLSI clocking problems. One approach to decreasing CDN power consumption is to use resonant clocks in the VLSI clock distribution network. For example see the following applications: U.S. App No. 61/502,619 (docket No. SC2011-195_PRV) Title: DISTRIBUTED LC RESONANT TANKS CLOCK TREE SYNTHESIS, and U.S. App No. 61/502,626 (docket No. SC2011-196_PRV) Title: DISTRIBUTED RESONANT CLOCK GRID SYNTHESIS, and U.S. App No. 61/502,635 (docket No. SC2011-244_PRV) Title: METHODS FOR INTEGRATED CIRCUIT C4 BALL PLACEMENT, inventor in all cases is Dr. Matthew Guthaus. Also see U.S. application Ser. No. 12/903,166 (US 2011/0090018 A1) that describes an inductor architecture for resonant clock distribution networks that allows for the adjustment of the natural frequency of a resonant clock distribution network, so that it achieves energy-efficient operation at multiple clock frequencies. Also see U.S. Ser. No. 12/903,168 (WO2011/046981A2) that describes an architecture allows for the energy-efficient operation of a resonant clock distribution network at multiple clock frequencies through the deployment of flip-flops that can be selectively enabled. Also see US20110090019A1, US20110090018A1, US20110084772A1, US20090027085A1, and WO2011046974A3. These applications and any publication thereof, and any and all publications referred to in this disclosure, are hereby incorporated by reference to the fullest extent allowed by law.

While resonant clock circuits have proven to be a viable way to reduce power consumption they have not been fully developed. For example, modern VLSI devices are capable of operating at multiple frequencies. One major reason for this is the desire to reduce power consumption, not only on the clock lines but on data lines. Consequently there is a need to achieve the benefits of resonance clock distribution networks and operation at multiple frequencies in the same device.

BRIEF DESCRIPTION OF THE INVENTION

The invention encompasses resonant clock meshes that resonate at multiple frequencies.

DETAILED DESCRIPTION OF THE INVENTION

The invention encompasses resonant clock meshes that resonate at multiple frequencies.

Dynamic frequency scaling is a common technique to save power in both the clock network and in data-path logic on computer chips since the power is proportional to CV²f where C is capacitance, V is the supply voltage and f is the frequency of operation. While prior resonant clock networks can save power by recycling energy in the clock network, they do not save any power in the data-path logic. Prior resonant clocks only work at a single resonant frequency.

The present invention solves this problem by creating a resonant clock mesh that can resonate at multiple frequencies. The basic concept used an inductor-capacitor (LC) tank that is attached to the clock mesh through an NMOS pass transistor. The gate of the transistor controls when the LC tank is electrically attached or when it is not attached to the clock mesh.

Similarly the clock mesh is also driven by tri-state clock drivers that can be enabled or disabled. The clock drivers must be capable of being disabled in order to save power. When all the LC tanks are disabled the clock must is in “buffered mode” and the drivers must be enabled to drive the clock mesh. While this is the most power efficient mode because it is non-resident, it is also the most flexible as it can be driven at any frequency by the drivers.

In the resonant modes, the resonant frequency is determined by how many LC tanks are enabled. The resonant frequency of a clock mesh is determined by 1/sqrt(LCg) where Cg is the fixed capacitance of the clock grid. For example, assume that Cg is 5 pF. The key observation is that at low frequencies the parasitic resistance of the clock mesh is not very large and a single LC tank can resonate the entire clock grid. For example, a 5 nH inductor will produce a 1 GHz resonant clock. If two additional LC tanks with 5 nH inductance are switched on in parallel, this provides an effective 1.6 nH inductance (Leff=1/(1/L+1/L2+1/L3)) and will produce a 1.75 GHz resonant clock. Switching on 4 more 5 nH inductors (7 total) in parallel will produce a 0.71 nH effective inductance and resonate at 2.67 Ghz.

In summary, the above technique enables multiple resonant clock modes for a 5 pF clock mesh:

-   1) Low-speed (1 GHz): A single (e.g. 5 nH) LC tank is attached to     the center of the clock mesh. -   2) Medium-speed (1.75 GHz): Two additional (e.g. 5 nH) LC tanks are     attached in each half of the clock mesh while the los-speed tank is     enabled. -   3) High-speed (2.67 GHz): Four more (e.g. 5 nH) LC tanks are     attached in addition to the previous three LC tanks.

The C in the LC tank is always assumed to enable a secondary resonant frequency and is sized much larger than Cg/n in each case where n is the number of enabled LC tanks.

In general the number of inductor-capacitor tanks can be much larger depending on the desired clock speed and the clock mesh capacitance. The size of the inductor in the LC tank is also not restricted to be 5 nH and can be selected for finer granularity frequency scaling. However, as the frequency goes up, the parasitic resistance becomes more important and the LC tanks must be distributed throughout the clock mesh. 

1. An integrated circuit, comprising: a clocked data network having a set of clock inputs; an inductor-capacitor (‘LC’) resonant network; and an electronic switch selectively connecting said inductor-capacitor resonant network to said clock inputs.
 2. The integrated circuit of claim 1, wherein said electronic switch includes an NMOS transistor.
 3. The integrated circuit of claim 2, wherein said NMOS transistor selectively connects said inductor-capacitor resonant network to said set of clock inputs.
 4. The integrated circuit of claim 2, further comprising a tri-state clock driver attached to said set of clock inputs, wherein said tri-state clock driver can be selectively disabled.
 5. The integrated circuit of claim 4 wherein the clock drivers may be disabled in order to save power.
 6. The integrated circuit of claim 4 wherein when all the inductor-capacitors are disabled the clock is in “buffered mode” and the drivers are enabled to drive the clock mesh.
 7. An integrated circuit, comprising: a clocked data network having a set of clock inputs; a first inductor-capacitor resonant network; a second inductor-capacitor resonant network; a first electronic switch for selectively connecting said first inductor-capacitor resonant network to said set of clock inputs; and a second electronic switch for selectively connecting said second inductor-capacitor resonant network to said set of clock inputs.
 8. The integrated circuit of claim 7, wherein said first inductor-capacitor resonant network resonates at a first frequency, said second inductor-capacitor resonant network resonates at a second frequency, and wherein said first inductor-capacitor resonant network and said second inductor-capacitor resonant network resonate at a third when connected together.
 9. The integrated circuit of claim 7, further including a tri-state clock driver attached to said set of clock inputs, wherein said tri-state clock driver can be selectively disabled.
 10. The integrated circuit of claim 7, wherein said first resonant tank network is distributed throughout the clock inputs.
 11. A resonant clock mesh that resonates at multiple frequencies comprising an inductor-capacitor (LC) tank in communication with said clock mesh through an NMOS pass transistor wherein the gate of the transistor controls when the LC tank is electrically attached or when it is not attached to the clock mesh.
 12. The resonant clock mesh of claim 11 wherein the clock mesh is driven by tri-state clock drivers that can be enabled or disabled in order to save power.
 13. The resonant clock mesh of claim 12 capable of multiple resonant clock modes for a 5 pF clock mesh, including: (i) low-speed (1 GHz) wherein a single LC tank is attached to the center of the clock mesh. (ii) medium-speed (1.75 GHz) wherein two additional LC tanks are attached in each half of the clock mesh while a loss-speed tank is enabled; and (iii) high-speed (2.67 GHz) wherein four more LC tanks are attached in addition to the previous three LC tanks. 